Advancements in Computer Aided Methods for EEG-based Epileptic
Detection
Malik Anas Ahmad
1,2
, Waqas Majeed
1
and Nadeem Ahmad Khan
1
1
Signal Image & Video Processing Lab, SBASSE, LUMS, Lahore, Pakistan
2
Robotics and Intelligent Systems Engineering Lab, SMME, NUST, Islamabad, Pakistan
Keywords: Epilepsy, Electroencephalography (EEG), Machine Learning, Biomedical Signal Processing.
Abstract: During the diagnosis of epilepsy, computer aided methods can significantly supplement a neurologist by
automatically identifying the epileptic patterns in an EEG. In the last decade immense amount of work has
been done in the field of EEG based computer aided diagnosis of epilepsy. Even after so much work these
tools are not getting used up to their full potential. In this paper we have very briefly discussed some of the
previously used signal processing and machine learning techniques which are proposed for epileptic pattern
detection. We have concluded this paper by suggesting some additions in the previous method which can
make these systems more helpful, detailed and precise for the neurologist.
1 INTRODUCTION
Epilepsy is a recurring neurological disorder, which
is characterized by excessive neural activity yield in
the brain. Almost 1% of the human population
suffers from epilepsy (WHO | Epilepsy 2012)
(Adelia, Zhoub & Dadmehrc 2003). Detection and
localization of abnormal, epilepsy-related brain
activity is very important for diagnosing and curing
of an epileptic disorder. Electroencephalogram
(EEG) is a method for recording of electrical activity
along the scalp. EEG signal represents fluctuations
in the voltage caused by the flow of ionic current in
the neurons. Epileptic seizures are accompanied by
unique patterns in EEG, and therefore EEG is widely
used to detect and locate the epileptic seizure and
zone.
Duration of a typical diagnostic EEG recording
varies from 40 minutes to a few hours. However,
prolonged EEG is opted if a seizure is not detected
in shorter recordings. A prolonged EEG can last as
long as 72 hours. Diagnostic procedures like this
generate a huge amount of data to be manually
inspected by the neurologist. Manual inspection of
all of the data for multiple patients could prove to be
a daunting task for a neurologist.
Computer assisted analysis of an EEG
supplements a neurologist in efficiently analysing
the EEG data. It highlights the epileptic patterns in
the EEG up to a significant level, thus reducing the
data to be analysed and lessening up the fatigue.
These analysis software tools apply different signal
processing and machine learning techniques on the
EEG data to detect the epochs with epileptic
patterns. Currently available commercial computer
assisted diagnosis tools for epilepsy are not a lot
user-friendly and lack adaptability/intelligence
(NeuroExplorer Home n.d.) (Neuralynx ~ Spike Sort
3D Software n.d.). These software tools require the
clinician to have an understanding of signal
processing algorithms to exploit the full potential of
the software (Tucker-Davis Technologies n.d.)
(Brain Products GmbH / Products & Applications /
Analyzer 2 n.d.). For this they hire technicians and
rely on them which make this analysing procedure
prone to misinterpretation and over-interpretation as
the manual marking get dependent on the expertise
of the technicians (Benbadis and Tatum 2003) rather
than the clinician himself.
In the next section we will briefly describe about
the existing work in the field of computer assisted
analysis of EEG for Epilepsy. Then in Section 3 we
will discuss the key factors involved in a computer
assisted analysis of EEG. After wards in Section 4
we will discuss the future research direction which
according to our analysis can be followed to
improve the existing work.
289
Anas Ahmad M., Majeed W. and Ahmad Khan N..
Advancements in Computer Aided Methods for EEG-based Epileptic Detection.
DOI: 10.5220/0004912802890294
In Proceedings of the International Conference on Bio-inspired Systems and Signal Processing (BIOSIGNALS-2014), pages 289-294
ISBN: 978-989-758-011-6
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
2 EXISTING WORK
EEG signals are non-stationary. Methods for
analysing non-stationary signals, such as Discrete
Wavelet Transform (DWT), Empirical Mode
Decomposition (EMD) and time-frequency analysis,
have been frequently used for automated seizure
detection using EEG signals. Epileptic seizures give
rise to changes in certain frequency bands which are
δ (0.4 – 4 Hz), θ (4 – 8 Hz), α (8 - 12 Hz) and β (12
– 30 Hz) (Adelia, Zhoub and Dadmehrc 2003).
That’s why usually the spectral content of the EEG
is used for diagnosis.
Usually the approach toward the detection of
epileptic patterns start with dividing the EEG data in
multiple small epochs, then multiple signal
processing steps are applied on these epochs to
extract out the features which are then used to
classify that epoch as epileptic or non-epileptic.
Majority of the work done in the line of epileptic
pattern detection usually do not involve fusion of
information obtained from multiple channels.
Instead, all the channels are processed in
series/sequentially, as if the EEG signal source is
one long signal instead of multiple parallel signals.
However Chang et al. (Chang et al., 2010)
appreciated the effects of multiple channels’ being
processed in parallel. They grouped 0.3 sec epochs
of multiple channels simultaneously in five different
clusters to avoid noise. Then they used FastICA to
discriminate between features, noise and background
of the signal. They then applied DWT with
Daubechies-4 (db4) as mother wavelet on the two
most independent parts of the signal. Then they
applied customized threshold to classify them as
epileptic or not. In this work Chang et al. showed
that consideration of multiple channels in group
improve the accuracy of your system.
Xanthopoulos et al. (Xanthopoulos et al., 2010)
used sliding variance on Continuous Wavelet
Transformed (CWT) epochs to detect the clinically
important epileptic patterns up to 98.625% accuracy.
Luo et al.’s (Luo and Luo 2010) work advocates
the importance of feature reduction techniques like
Principal Component Analysis (PCA). He evaluated
the effectiveness of six features. The PCA showed
that almost three of the six features has contribution
ratio of 79 %. So discarding of other three features
could improve the processing time without a
significant damage to the classification accuracy.
His stance was verified by the Artificial Neural
Network (ANN) classifier whose accuracy only
dropped by 2.5% with the exclusion of three
features. The six features were Hurst Index,
Standard Deviation and Periodicity, Shannon
Entropy, Approximate Entropy and periodicity of
smoothed EEG signal, where the first three are the
most contributing features.
Petersen et al.’s (Petersen et al., 2011) work
shows that to detect the generalised seizure using
only one channel, usage of the energy of the detail
coefficients of the wavelet transformed one second
epoch of a F7-FP1 in an SVM classifier can result
with as good as 99.1% sensitivity.
In Abdullah et al.’s (Abdullah, Abdullah and
Abdullah 2012) work Hidden Markov Model
(HMM) was applied on vector quantized Stationary
Wavelet Transform coefficients of intracranial EEG
signal. Their work resulted with 96.38% and 96.82%
average sensitivity and specificity respectively.
Sousa et al. (Sousa, Mendes and Ribeiro, 2012)
studied how rhythms analysis identifies the various
events recorded in the EEG. Their work resulted
with 95.5% accuracy.
Abdullah et al. (Abdullah, Saufiah and Ibrahim
2012) simultaneously used features extracted from
DWT and Fourier transform in an ANN classifier.
Their work resulted with 98.889% accuracy.
Khan et al. (Khan, Rafiuddin and Farooq 2012)
used energy and normalized coefficients of variance
of multi-level DWT coefficients. These features
were used by a Linear Discriminant Analysis (LDA)
to classify the EEG epochs with an accuracy of
91.8%.
Due to the heavy computational burden of
marching pursuit (MP) algorithm (Guo et al., 2012)
proposed a reduce complexity of sparse
representation to adopt harmony search method in
searching the best atoms. Their efforts resulted with
huge amount of improvement in the latency. Wang
et al. (Wang et al., 2012) used these features with
Adaptive Neuro-Fuzzy Inference System (ANFIS)
as a classifier. Here they integrated the artificial
neural networks and fuzzy logic together. Their
effort resulted in 97.4% accuracy.
Choi et al. (Choi, Zeng and Qin, 2012) selected
the optimal frequency band features by using the
Sequential Floating Forward Selection (SFFS)
algorithm. These features were fed to three types of
classifier. These classifiers were linear, quadratic
and cubic discriminant function. They found QDF
with best accuracy which was 97.2%.Sezer et al.
(Sezer, Işik and Saracoğlu, 2012) tested multiple
types of ANN and found Elman method to be most
accurate along with DWT as feature extraction
method.
Alam et al. (Alam and Bhuiyan, 2013) used the
higher order statistical parameters like variance,
BIOSIGNALS2014-InternationalConferenceonBio-inspiredSystemsandSignalProcessing
290
skewness and kurtosis of empirical mode
decomposed EEG signal with ANN.
Seng et al.’s (Seng et al., 2013) used simple
features like mean, variance, dominant frequency,
mean of power spectrum and the signal data itself of
the EEG epochs in linear SVM. They tried multiple
epoch sizes which were 23.6 sec, 11.5 sec, 5.8 sec,
and 1 sec. The result showed that smaller epoch size
results in better accuracy whereas bigger epoch size
results in better latency.
Ocbagabir et al. (Ocbagabir, Aboalayon and
Faezipour 2013) used Butterworth band pass filter to
decompose the EEG signal into 5 sub-bands and
then used Energy, Entropy, and Standard Deviation
as features for a SVM classifier. This classification
approach resulted in 95% accuracy.
Kaleem et al. (Kaleem, Guergachi and Krishnan
2013) applied a novel variation of the EMD called
Empirical Mode Decomposition-Modified Peak
Selection (EMD-MPS). They used Energy, sum of
the amplitude spectrum, sparsity of the amplitude
spectrum and the sum of derivative of the amplitude
spectrum as the input features to a simple 1-NN
classifier which resulted with 98.2% accuracy.
Murugavel et al. (Muthanantha Murugavel et al.,
2013) used a novel feature named as Combined
Seizure Index as a feature which they extracted from
wavelet packet coefficients. These features in a
multi scale SVM resulted with 97.3% accuracy.
3 DISCUSSION
After providing a short literature survey we proceed
to discuss the state-of-the art research from different
important perspectives.
3.1 EEG Databases
There are two major databases for scalp EEG which
are used for validating the performance of the
automatic epileptic pattern detection algorithms.
First of the two data sets are from Klinik fur
Epileptologie at the Universitat Bonn, German
(Klinik fur Epileptologie, Universitat Bonn n.d.).
This dataset has two sets of 100-channel EEG data
consisting of normal and epileptic subjects with
segment duration of 23.6sec, 4096 sampling point
and 173.61 Hz sampling frequency. The first EEG
data set is a scalp EEG of 5 normal subjects. The
other EEG data set is a intracranial EEG of 5
epileptic patients, recorded during the occurrence of
the epileptic seizures.
The second most used EEG database is the
CHBMIT scalp EEG database (Goldberger et al.
2000). It been provided by Children Hospital Boston
and is available at physionet website (Shoeb, 2000).
This database consists of 916 hours of continuous
scalp EEG recordings collected from 24 subjects
suffering from intractable seizures. Out of 664 EEG
recordings files, 129 files consisted of one or more
seizures. The 23 channel EEG signal has a sampling
frequency of 256 Hz with 16 bit resolution.
In the following lines we will discuss some of
our observations on these databases.
3.1.1 Size of Database & over-fitting
The first database is less versatile in comparison to
the second one and it also has lesser number of
examples. This makes the classifiers trained on the
first dataset more prone to over-fitting. Probably this
is the reason behind algorithms not performing with
the cited accuracy on the real life data.
3.1.2 Labelling
Another issue with both of these databases is that the
labelling does not specify the epileptic pattern type.
Apparently they are labelled for generalized 3Hz
spike & wave which is a symptom for absence
seizure which is one of many types of epilepsy.
3.2 Epileptic Patterns
EEG recorded from epileptic patient exhibits
distinctive signal patterns. Patterns like Spikes,
Sharp wave, Benign epileptiform discharges of
childhood, Spike-wave complexes, Slow spike-wave
complexes, 3-Hz spike-wave complexes, Polyspikes,
Hypsarrhythmia, Seizure pattern, Status pattern are
considered as epileptiform (Lüders and Noachar,
2000; Noachtar et al., 1999).
Mostly 3Hz spike & wave detection has
remained the focus of the past work. Whereas other
epileptic patterns detection are usually ignored.
Sousa et al. (Sousa, Mendes and Ribeiro, 2012) are
among those few people who have addressed the
detection of multi-type epileptic patterns.
3.3 Feature Extraction & Reduction
3.3.1 Epoch Size
The choice of epoch size depends a lot on the
sampling frequency and feature extraction
techniques. Epoch size as low as 0.3 sec (Chang et
al., 2010) and as high as 23.6 sec (Ocbagabir,
Aboalayon and Faezipour, 2013) has been cited, but
AdvancementsinComputerAidedMethodsforEEG-basedEpilepticDetection
291
the most commonly used epoch size is of 1 sec. A
comparison among 23.6 sec, 11.5 sec, 5.8 sec, and 1
sec in Seng et al.’s work resulted with 1 sec epoch
size to be working best in terms of accuracy.
3.3.2 Feature Types
The most commonly used feature extraction method
is WT with db4 or Morelet as a mother wavelet. This
also seems to be a promising method yielding the
best performance figures. Majority of the algorithms
use detailed coefficients’ energy, variance, standard
deviation, entropy, mean, maxima and minima or
any combination or slight modification of these as
features whereas few algorithms use the detailed
coefficients without any modification.
Other than Wavelets, Fourier transform, EMD,
MP, SFFS or their modified versions has also been
cited as the feature extraction techniques.
3.3.3 Feature Reduction
There are few examples where some authors like
Luo et al. (Luo and Luo, 2010) have used feature
reduction techniques like PCA before classifying.
The motivation behind applying reduction is to
avoid noise and redundancy.
3.4 Classifiers
SVM, Linear/ Quadratic/ Cubic Discriminant
Analysis, ANN, Genetic Algorithms (GA), HMM,
Fuzzy Based classifier and the adaptive thresholding
techniques have been cited to be used as a
classification method.
Support Vector Machine (SVM) is the most
widely used classifier. Multiple comparative studies
like (Yuan, 2010), (Mohamed Bedeeuzzaman,
Farooq and Khan, 2010), and (Harikumar,
Vijaykumar and Palanisamy, 2011) shows that SVM
yielded one of the best with least amount of latency
alongside different and versatile feature extraction
method. Yuan showed that it works 0.44% more
accurate than Neural Networks.
In some particular conditions number of these
classifier has been cited to perform with 100%
accuracy. This accuracy is probably a result of over-
fitting as same techniques when applied on real life
data do not result with such high accuracy. So there
should be method which should keep these
algorithms improving their detection with increment
in the available examples. There should be a method
introduced where a neurologist can suggest
corrections as per his desire while observing wrong
marking by the computer aided system and the
system should learn from that correction.
3.5 Latency
To make these computer aided system useable in
real life condition, latency is important. There are
multiple reasons behind an increment of latency. It is
the training process which usually takes a lot of
time. Other then the computation involved during an
algorithm, latency also largely depends up on the
processing power, speed and size of the memory
devices in a machine which is running the algorithm.
Selection of appropriate Epoch size is not only
important for batter accuracy but it also affects the
latency. According to Seng et al. (Seng et al., 2013)
shortening the epoch size improves the accuracy on
the cost of latency.
Different algorithms result in different ways
when training examples are increased. Nasehi et al.
(Nasehi and Pourghassem 2011) reported that their
algorithms’ latency and detection delay got
decreased with the increment in training examples
with seizures. Geetha et al. (Geetha and
Geethalakshmi, 2011) and Abdullah et al.
(Abdullah, Saufiah and Ibrahim, 2012) describe that
after a certain amount of training examples,
increment in the training examples worsen the
accuracy and latency.
4 FUTURE RESEARCH
DIRECTIONS
In this section we will highlight the shortcomings of
the existing approaches and suggest some possible
future research directions.
Firstly, most of the existing work is about
detecting the generalized 3Hz spike & wave pattern
which is a symptom for absence seizure. To detect
localized epileptic activities, each channel should be
classified separately. This addition in the current
method will help in diagnosing focal epilepsy.
Secondly, many types of epilepsy are diagnosed
by EEG. These epilepsies are identified by unique
patterns or combination of few epileptic patterns.
3Hz spike & wave is just one of the many. Noachtar
et al. described ten types of epileptic patterns. To
counter this issue there should be exclusive and
independent trainers for each channel and each
channel should have exclusive and independent
trainer for each epileptic patterns. In this way we
BIOSIGNALS2014-InternationalConferenceonBio-inspiredSystemsandSignalProcessing
292
could detect, classify and label all types of epileptic
patterns.
Commercially available EEG analyzing software
tools are too user dependent. They need the user to
have a prior knowledge of signal processing to fully
exploit the full potential of this software. In this case
neurologist seeks the help of neurotechnicians,
which in case of inexperience or naive
neurotechnicians may lead to misinterpretation or
over-interpretation.
Seizure detection methods should be able to
improve their detection capability after initial
training. Addition of some post development
training mechanism can help the system improve its
performance over time. One way to handle this issue
is that after initial training and classification of the
EEG, a user interface showing the labelled epileptic
wave should allow the neurologist to mark an
epileptic chunk a.k.a “an epoch” as wrongly
classified. These markings will be saved in the
background as training example and they will be
later used to retrain the classifier alongside previous
examples. This addition will make the classifier
improve its detection with passage of time.
There are few papers that have cited that
increasing training data above a certain point can
drop down the accuracy, for this we suggest that
before classifier’s training feature reduction
techniques like PCA should be applied so that we
can remove the noise and redundancy without
compromising the important data.
In long term, this may make the system adapt
itself according to a neurologist’s corrective
marking, thus the system may start mimicking
neurologist detection by time regardless of any
merit. This is in accordance to our motivation i.e.
facilitating the neurologist. Another issue is that of
personalizing this software tool according to a
neurologist’s liking. Neurologists some time have a
disagreement with each other’s diagnostic markings.
So instead of forcing those to follow our brand of
detected patterns our suggested solution will resolve
both issues at a time. It will adapt its classification
ability as per every neurologist own desire.
(Noachtar & Rémi 2009)
5 CONCLUSIONS
Epilepsy is an important neurological disorder.
Computer assisted analysis of EEG for diagnosing
Epilepsy significantly helps a neurologist. To avoid
misinterpretation and over-interpretation a computer
assisted system should be user friendly, accurate,
robust and above informative. Lots of work has been
done in this regard. With the addition of our
suggested steps in the existing work robustness and
the classification accuracy can be improved. Other
than the approach we will like to suggest that there
should be a post development training system
attached to our-all detection algorithm so that it may
improve itself from the correction marked by the
neurologist. Though with the passage of time,
training system will try to adapt itself according to
the neurologist choice and its classification will get
biased as per his choice, but the whole point of this
effort was to supplement the neurologist.
REFERENCES
Abdullah, M. H., Abdullah, J. M. & Abdullah, M. Z. 2012,
'Seizure Detection by Means of Hidden Markov Model
and Stationary Wavelet Transform of
Electroencephalograph Signals', IEEE-EMBS
International Conference on Biomedical and Health
Informatics, IEEE, Hong Kong.
Abdullah, A. A., Saufiah, A. R. & Ibrahim, A 2012,
'Development of EEG-based Epileptic Detection using
Artificial Neural Network', International Conference
on Biomedical Engineering (ICoBE), IEEE, Penang.
Adelia, H, Zhoub, Z & Dadmehrc, N 2003, 'Analysis of
EEG records in an epileptic patient using wavelet
transform', Journal of Neuroscience Methods, vol 123,
no. 1, pp. 69–87.
Alam, S. M. S. & Bhuiyan, M. I. H. 2013, 'Detection of
Seizure and Epilepsy Using Higher Order Statistics in
the EMD Domain', IEEE Journal of Biomedical and
Health Informatics, vol 17, no. 2, pp. 312-318.
Benbadis, S.R. & Tatum, WO 2003, 'Overinterpretation of
EEGs and misdiagnosis of epilepsy', Neurophysiol, vol
20, pp. 42-44.
Brain Products GmbH / Products & Applications /
Analyzer 2, viewed 17 May 2013, <http://
www.brainproducts.com/productdetails.php?id=17>.
Chang, H. Y., Yang, S. C., Lan, S. H. & Chung, P. C.
2010, 'Epileptic seizure detection in grouped multi-
channel EEG signal using ICA and wavelet transform',
International Symposium on Circuits and Systems
(ISCAS), IEEE, Paris.
Choi, K. S., Zeng, Y & Qin, J 2012, 'Using sequential
floating forward selection algorithm to detect epileptic
seizure in EEG signals', International Conference on
Signal Processing (ICSP), IEEE, Beijing.
Geetha, G & Geethalakshmi, S. N. 2011, 'Detecting
Epileptic Seizures Using Electroencephalogram: A
New and Optimized Method for Seizure Classification
Using Hybrid Extreme Learning Machine',
International Conference on Process Automation,
Control and Computing (PACC), IEEE, Coimbatore.
Goldberger, A. L, Amaral, L, Glass, L, Hausdorff, J. M.,
Ivanov, P. C., Mark, R. G, Mietus, J. E, Moody, G. B,
AdvancementsinComputerAidedMethodsforEEG-basedEpilepticDetection
293
Peng, C. K & Stanley, H. E 2000, 'PhysioBank,
PhysioToolkit, and PhysioNet: Components of a New
Research Resource for Complex Physiologic Signals',
Circulation , vol 23, no. 101, pp. 215-220, viewed 11
November 2013, <http://physionet.org/pn6/chbmit/>.
Guo, P, Wang, J, Gao, XZ & Tanskanen, JMA 2012,
'Epileptic EEG Signal Classification with Marching
Pursuit based on Harmony Search Method',
International Conference on Systems, Man, and
Cybernetics, IEEE, Seoul.
Harikumar, R, Vijaykumar, T & Palanisamy, C 2011,
'Performance analysis of fuzzy techniques hierarchical
aggregation functions decision trees and Support
Vector Machine (SVM)for the classification of
epilepsy risk levels from EEG signals', Recent
Advances in Intelligent Computational Systems
(RAICS), IEEE, Trivandrum.
Kaleem, M, Guergachi, A & Krishnan, S 2013, 'EEG
Seizure Detection and Epilepsy Diagnosis using a
Novel Variation of Empirical Mode Decomposition',
International Conference of the EMBS, IEEE, Osaka.
Khan, Y. U., Rafiuddin, N & Farooq, O 2012, 'Automated
seizure detection in scalp EEG using multiple wavelet
scales', IEEE International Conference on Signal
Processing, Computing and Control (ISPCC), IEEE,
Waknaghat Solan.
Klinik fur Epileptologie, Universitat Bonn, viewed 11
November 2013, <http://epileptologie-bonn.de/cms/
front_content.php?idcat=193&lang=3&changelang=3>.
Lüders, H. O. & Noachar, S 2000, Atlas and classification
of electroencephalography, Elsevier Science Health
Science Division.
Luo, K & Luo, D 2010, 'An EEG Feature-based Diagnosis
Model for Epilepsy', International Conforence on
Computer Application and System Modeling
(ICCASM), IEEE, Taiyuan.
Mohamed Bedeeuzzaman, V, Farooq, O & Khan, YU
2010, 'Automatic Seizure Detection Using Higher
Order Moments', International Conference on Recent
Trends in Information, Telecommunication and
Computing, IEEE, Kochi, Kerala.
Muthanantha Murugavel, AS, Ramakrishnan, S,
Maheswad, U & Sabetha, BS 2013, 'Combined
Seizure Index with Adaptive Multi-Class SVM for
epileptic EEG classification', International Conference
on merging Trends in VLSI, Embedded System, Nano
Electronics and Telecommunication System
(ICEVENT), IEEE, Tiruvannamalai.
Nasehi, S & Pourghassem, H 2011, 'Epileptic Seizure
Onset Detection Algorithm Using Dynamic Cascade
Feed-Forward Neural Networks', International
Conference on Intelligent Computation and Bio-
Medical Instrumentation (ICBMI), IEEE, Wuhan,
Hubei.
Neuralynx ~ Spike Sort 3D Software, viewed 20 May
2013, <http://neuralynx.com/
research_software/spike_sort_3d>.
NeuroExplorer Home, viewed 5 May 2013,
<http://www.neuroexplorer.com/>.
Noachtar, S, Binnie, C, Ebersole, J, Mauguière, F,
Sakamoto, A & Westmoreland, B 1999, 'The
International Federation of Clinical Neurophysiology:
a glossary of terms most commonly used by clinical
electroencephalographers and proposal for the report
form for the EEG findings', Clinical Neurophysiology,
vol 52, pp. 21-41.
Noachtar, S & Rémi, J 2009, 'The role of EEG in epilepsy:
A critical review', Epilepsy & Behavior
, pp. 22-33.
Ocbagabir, H. T., Aboalayon, K. A. I & Faezipour, M
2013, 'Efficient EEG analysis for seizure monitoring
in epileptic patients ', Long Island Systems,
Applications and Technology Conference (LISAT),
IEEE, Farmingdale, New York.
Petersen, E. B., Henriksen, J. D., Mazzarettoa, A, Kjær,
TW, Thomsen, C. E. & Sorensen, H. B. D. 2011,
'Generic Single-Channel Detection of Absence
Seizures', Annual International Conference of the
EMBS, IEEE, Boston.
Seng, C. H, Demirli, R, Khuon, L & Bolger, D 2013,
'Seizure Detection in EEG Signals Using Support
Vector Machines', Northeast Bioengineering
Conference (NEBEC), IEEE, Philadelphia.
Sezer, E, Işik, H & Saracoğlu, E 2012, 'Employment and
Comparison of Different Artificial Neural Networks
for Epilepsy Diagnosis from EEG Signals', Journal of
Medical Systems, vol 36, no. 1, pp. 347-362.
Shoeb, A 2000, CHB-MIT Scalp EEG Database, viewed
11 November 2013, <http://physionet.org/pn6/chbmit/>.
Sousa, T, Mendes, P & Ribeiro, J 2012, 'The impact of
rhythms analysis technique on electrographic seizure
detection (EEG)', 2nd Portuguese Meeting in
Bioengineering (ENBENG), IEEE, Coimbra.
Tucker-Davis Technologies, viewed 20 May 2013,
<http://www.tdt.com/index.htm>.
Wang, J, Gao, XZ, Tanskanen, JMA & Guo, P 2012,
'Epileptic EEG Signal Classification with ANFIS
based on Harmony Search Method', International
Conference on Computational Intelligence and
Security (CIS), IEEE, Guangzhou.
WHO | Epilepsy 2012, <http://www.who.int/mediacentre/
factsheets/fs999/en/>.
Xanthopoulos, P, Rebennack, S, Liu, C. C, Zhang, J,
Holmes, G. L., Uthman, B. M. & Pardalos, P. M.
2010, 'A Novel Wavelet Based Algorithm for Spike
and Wave Detection in Absence Epilepsy',
International Conference on BioInformatics and
BioEngineering (BIBE), IEEE, Philadelphia.
Yuan, Y 2010, 'Detection of Epileptic Seizure Based on
EEG Signals', International Congress on Image and
Signal Processing (CISP2010), IEEE, Yantai.
BIOSIGNALS2014-InternationalConferenceonBio-inspiredSystemsandSignalProcessing
294
